Spelling suggestions: "subject:"five exclusion"" "subject:"fine exclusion""
1 |
Riqueza e abundância de espécies em diferentes compartimentos da comunidade vegetal no gradiente fisionômico do cerrado em Assis, SPNeri, Ana Carolina Abrão 03 August 2012 (has links)
Made available in DSpace on 2016-06-02T19:29:58Z (GMT). No. of bitstreams: 1
5454.pdf: 8508696 bytes, checksum: 427d6057ce7582f3ad197b6887b04a5e (MD5)
Previous issue date: 2012-08-03 / Universidade Federal de Minas Gerais / Fire protection has caused ongoing changes in savannas throughout the world, with the expansion of the woody component over more open vegetation. Although these changes have been documented at the landscape level, some questions regarding changes in the floristic composition of communities and the regeneration mechanisms present in different physiognomies remain. The aim of this study was to evaluate species richness and abundance in several components of the community (seed rain, seed bank, and the understory, intermediate, and upper strata) in a cerrado area after 50 years of fire protection. This research was developed along the physiognomic gradient (typical cerrado, dense cerrado and cerradão) existent at Assis Ecological Station, São Paulo state. Seed rain, seed bank, and floristic composition of the three strata were sampled in 30 20 x 50 m plots, 10 plots in each physiognomy. Differences between physiognomies and between seasons were analyzed by means of uni- and multivariate analysis of variance and by linear regression and correlation. Basal area was used as a surrogate of biomass along the physiognomic gradient. Species richness decreased across the whole community for the ground layer and intermediate layer along the successional gradient. In seed rain and seed bank, the floristic composition and abundance differed significantly between the three physiognomies. In seed rain, trees and saplings, mostly generalist species, represented the predominant growth forms, both in relative abundance, as in richness. In the seed bank, herbaceous species presented the highest values for richness and abundance in all physiognomies. The seed rain and seed bank are important as regeneration strategies for a group of species, usually generalists. The homogenization of vegetation structure and floristic composition puts under question the management strategies currently employed in areas designed for Cerrado conservation. Considering that Cerrado fragmentation has concentrated its gene pool in small, isolated remnants and that some plant and animal species are restricted to more open physiognomies, a more refined discussion of the implications that management regimes may have on these communities is essential. / A proteção contra o fogo tem causado mudanças contínuas em savanas pelo mundo, com a expansão do componente arbóreo sobre fisionomias mais abertas. Essas mudanças têm sido documentadas no nível de paisagem, mas ainda persistem questões sobre as mudanças florísticas na comunidade e os mecanismos de regeneração nas diferentes fitofisionomias do Cerrado. O objetivo deste estudo foi avaliar a riqueza e abundância de espécies em diferentes compartimentos da comunidade (chuva de sementes, banco de sementes e estratos inferior, intermediário e superior) e em diferentes estações do ano em uma área de cerrado protegida do fogo há 50 anos. Esta pesquisa foi desenvolvida no gradiente fisionômico (cerrado típico, cerrado denso e cerradão) da Estação Ecológica de Assis, SP. As coletas da chuva de sementes, banco de sementes e o levantamento florístico nos três estratos da vegetação foram conduzidos em 30 parcelas de 20 × 50 m, sendo 10 parcelas para cada fisionomia. As diferenças entre fisionomias e entre estações do ano foram analisadas por meio de Análise de Variância Univariada e Multivariada e por meio de análise de correlação e regressões lineares. A área basal foi utilizada como representante da variável biomassa no gradiente fisionômico. Houve uma diminuição na riqueza para toda a comunidade (três estratos em conjunto), para o estrato inferior e para o estrato intermediário ao longo do gradiente fisionômico. Na chuva e no banco de sementes, a composição florística e a abundância diferiram significativamente entre as três fisionomias. Na chuva de sementes, as espécies arbóreas e arvoretas, em sua maioria generalistas, representaram as formas de crescimento predominantes, tanto em abundância relativa, quanto em riqueza. No banco de sementes, as espécies herbáceas apresentaram os maiores valores para riqueza e abundância, em todas as fisionomias. A chuva e o banco de sementes constituem estratégias de regeneração importantes para um grupo restrito de espécies, em geral, generalistas. O processo de homogeneização da vegetação, quanto à estrutura e composição florística, coloca sob questão as estratégias de manejo atualmente empregadas nas áreas destinadas à conservação do Cerrado. Considerando que a intensa fragmentação do Cerrado tem concentrado seu pool gênico em remanescentes pequenos e isolados e que há um conjunto de espécies de fauna e flora restritas às fisionomias mais abertas, um debate mais cuidadoso sobre as implicações de manejo para estas comunidades se faz essencial.
|
2 |
The long-term effects of fire frequency and season on the woody vegetation in the Pretoriuskop Sourveld of The Kruger National ParkO’Regan, Sean Patrick 01 March 2007 (has links)
Student Number : 9008538J -
MSc Dissertation -
School of Biology -
Faculty of Science / O’Regan SP, 2005. The long-term effects of fire frequency and season on the woody vegetation in the
Pretoriuskop sourveld of the Kruger National Park. MSc Dissertation, University of the Witwatersrand,
Johannesburg.
The role of fire in the management of conservation areas has historically been a contentious issue in which
traditional agricultural principles and ever-changing conservation principles tend to collide. The Kruger
National Park (KNP) in the early 1950s was no exception where the appropriate use of fire and its ecosystem
consequences were hotly debated. The controversy surrounding the management of fire in the KNP
highlighted the significant lack of understanding of fire and its role in the ecosystem and because of this
controversy, the Experimental Burn Plot (EBP) experiment was established in 1954. The EBP experiment
comprised 12 treatments, and a pseudo-randomised block design was used in which the 12 fire treatments
were replicated four times each in four of the six major vegetation zones identified at the time. The EBP
experiment originally comprised 192 experimental plots approximately 7 Ha in size each and covered
approximately 12 km2 in the KNP. The twelve fire treatments were an annual burn in August, biennial and
triennial burns in February, April, August, October, and December, and a control on which fire was excluded.
Despite having been plagued with negative assessments from internal and external researchers from its
inception, the EBP experiment was meticulously maintained, and it has now become a valuable research
asset in the KNP.
Four replicates of twelve plots each were located in the Pretoriuskop sourveld landscape of the KNP. These
replicates were named Fayi, Kambeni, Numbi, and Shabeni after nearby landmarks. The Pretoriuskop region
is a moist infertile mesic-savanna, which experiences on average 744mm of rain annually. The dominant tree
species in Pretoriuskop are Dichrostachys cinerea and Terminalia sericea and the dominant grass species is
Hyperthelia dissoluta. A baseline survey of the woody vegetation was done on all the Pretoriuskop plots in
1954 by HP Van Der Schijff. A second survey of the woody vegetation on all the Pretoriuskop plots was done
in 1996 by SP O’Regan. This provided a 42-year period of treatment application over which the effects of fire
frequency and season on the woody vegetation of the Pretoriuskop region were studied.
The aim of this study was to investigate the long-term effects of the twelve fire treatments on the density,
structure, and species composition of the woody vegetation in Pretoriuskop. The objectives of this study
were:
1. To carry out a complete re-survey of the trees and shrubs on the Pretoriuskop EBPs using similar
methods as those used in the baseline survey in 1954.
2. To capture into a digital format pertinent woody vegetation survey data from surveys that had been
conducted on the Pretoriuskop EBPs between 1954 and 1996.
3. To compare the density, structure, and composition of the woody vegetation on the Pretoriuskop
EBPs between 1954 and 1996, to determine the effects of fire on the woody vegetation of
Pretoriuskop.
4. To investigate the history of the Kruger National Park Experimental Burn Plots experiment.
The four replicates in the Pretoriuskop region were found generally to have very similar woody vegetation
traits (density, species composition, and structural composition). However, the EBPs were established and
surveyed in two distinct phases, the first phase comprised the control, August Annual, and the Biennial plots,
and the second phase comprised the Triennial plots. The baseline structural composition of the plots
established in the first phase was different from the structural composition of the plots in the second phase.
Furthermore, the Pretoriuskop EBPs are located in two distinct vegetation types, namely the open and the
closed Terminalia sericea \ Combretum woodlands of the Pretoriuskop region. The Numbi and Shabeni
replicates are in the open Terminalia sericea \ Combretum woodlands, and the Kambeni and Fayi replicates
are in the closed Terminalia sericea \ Combretum woodlands. It was found that the species composition of
the plots was influenced by the location of the plots in the different vegetation types.
The exclusion of fire in the Pretoriuskop sourveld results in an increase in the density of the overstorey and
understorey woody vegetation, and an increase in the number of species, species diversity, and species
evenness. This is because fire sensitive and fire intolerant woody species become more abundant as the
period between fires increases. In Pretoriuskop, there is no evidence of relay floristic succession, because
fire sensitive and fire intolerant woody species do not replace fire tolerant species. Instead, the floristic
succession is accumulative and fire tolerant, fire sensitive, and fire intolerant woody species coexist as the
period between fires increases. Woody species tolerant of frequent fires in Pretoriuskop are Albizia
versicolor, Catunaregam spinosa, Lonchocarpus capassa, Pavetta schumanniana, Senna petersiana,
Strychnos madagascariensis, and Turraea nilotica. Woody species that are sensitive or intolerant of fire in
Pretoriuskop are Acacia swazica, Bauhinia galpinii, Combretum mossambicense, Commiphora neglecta,
Croton gratissimus, Dalbergia melanoxylon, Diospyros lycioides, Diospyros whyteana, Euclea natalensis,
Hyperacanthus amoenus, Kraussia floribunda, Ochna natalitia, Olea europaea, Psydrax locuples,
Putterlickia pyracantha, Tarenna supra-axillaris, and Zanthoxylum capense. Dichrostachys cinerea and
Terminalia sericea were found to dominate in areas that had been burnt frequently as well as areas where
fire has been excluded. The change in the density of the woody vegetation as the inter-fire period increases
is not linear but rather J shaped with an initial decrease in the density as the inter-fire period increases from
1 year to 3 years. This initial decrease in density is the result of a loss of very short (<1m tall) woody
individuals. In contrast, there is no initial decrease in the number of tree equivalents (phytomass) of the
woody vegetation as the inter-fire period increases. After the initial decrease in the density of the woody
vegetation, the density increases as the inter-fire period increases beyond 3 years. Generally in
Pretoriuskop, post fire age of the vegetation was found to be an important factor affecting the structure of the
woody vegetation, and as the inter-fire period increases the number of structural groups, the structural
diversity, and the structural evenness of the woody vegetation increases. As the inter-fire period increases
the number of single-stem individuals relative to the number of multi-stem individuals increases, and the
average height of the woody vegetation increases. The findings regarding the effects of fire frequency on the
Pretoriuskop EBPs were similar to the findings on other fire experiments in mesic African savannas. The
finding on the Pretoriuskop EBPs differed from the findings in other fire trials that were in arid savannas in
Africa. Generally, the exclusion of fire in moist savannas (> 600 mm of rain annually) results in the woody
vegetation becoming denser, while the exclusion of fire in arid to semi-arid savannas (< 600mm of rain
annually) does not result in the woody vegetation becoming denser.
In Pretoriuskop, fires occurring in summer between December and February have a different impact on the
density, species composition, and structure of the woody vegetation than fires occurring in winter between
August and October. Furthermore, fires occurring in April have a different impact on the density, species
composition, and structure of the woody vegetation in Pretoriuskop. Woody vegetation burnt by summer fires
is denser than woody vegetation burnt by winter fires. The number of species and species diversity of the
woody vegetation is also higher in vegetation burnt by summer fires in comparison with vegetation burnt by
winter fires. The density and species composition of woody vegetation in areas that have been burnt in
summer fires is more similar to areas where fire has been excluded than to areas that have been burnt in
winter fires. The woody species associated with vegetation burnt in summer fires and where fire has been
excluded are Euclea natalensis, Antidesma venosum, Diospyros lycioides, Phyllanthus reticulatus, Grewia
flavescens, Grewia monticola, Ochna natalitia, Peltophorum africanum, Rhus pyroides, Diospyros
mespiliformis, Rhus transvaalensis, Securinega virosa, Putterlickia pyracantha, Rhus pentheri, Commiphora
neglecta, Heteropyxis natalensis, and Olea europaea. Structurally the average height of the woody
vegetation is taller in areas burnt by winter fires than in areas burnt by summer fires. The woody vegetation
in areas burnt in summer fires have more single-stem individuals relative to multi-stem individuals than in
areas burnt in winter fires. The structural composition of areas burnt in summer fires is more similar to areas where fire has been excluded than with areas burnt in winter fires. The structure of the woody vegetation in
areas burnt in winter fires is generally dominated by multi-stem individuals that are 0-1m tall or 3-5m tall. The
structure of the woody vegetation in areas burnt in summer fires or where fire has been excluded is
dominated by both single-stem and multi-stem individuals of all heights and basal diameters. Findings
regarding the effect of early dry season fires (April) in comparison with late dry season fire (August) on the
woody vegetation are consistent with the findings on other fire trails in Africa. However, a comparison of all
the fire-timing treatments between the Pretoriuskop and Satara EBPs in the KNP reveals that the timing of
fires affects the woody vegetation differently in different areas even when the affects at certain times appear
similar.
The data collected on the Pretoriuskop EBPs reveals that there have been significant changes in the woody
vegetation in Pretoriuskop between 1954 and 1996. The density of the woody vegetation increased between
1954 and 1996 by almost 200%. The number of species and the species diversity of the woody vegetation
also increased between 1954 and 1996. In 1954, there were approximately equal numbers of single-stem
and multi-stem individuals, while in 1996 there were more multi-stem individuals than single-stem individuals.
The increase in atmospheric CO2 levels between 1954 and 1996 is believed to have been a factor that has
driven the changes in the woody vegetation of Pretoriuskop between 1954 and 1996.
|
3 |
Mixed-conifer forests of central Oregon : structure, composition, history of establishment, and growthMerschel, Andrew G. 14 December 2012 (has links)
The structure and composition of mixed-conifer forest (MCF) in central Oregon has been altered by fire exclusion and logging. The resulting increased density, spatial contagion, and loss of fire resistant trees decrease the resiliency of this ecosystem to fire, drought, and insects. The historical and current composition and structure of MCF are characterized by steep environmental gradients and a complex mixed-severity fire regime. This inherent variation makes it difficult to determine the magnitude of anthropogenic effects and set objectives for restoration and management. As a result, there is a lack of consensus regarding how MCF should be managed and restored across the landscape. My primary research objectives were to: (1) Characterize the current structure and composition of MCF and how these vary with environmental setting; and (2) Characterize establishment and tree growth patterns in MCF in different environmental settings. To address these objectives, I collected field data on structure and composition and increment cores across a range of environmental conditions in MCF of the eastern Cascades and Ochoco Mountains.
I used cluster analysis to identify four stand types based on structure and composition in the eastern Cascades study area and four analogous types in the Ochoco Mountains study area. Variation in understory composition and the presence of large diameter shade tolerant species distinguish each type. Stand types occupied distinct environmental settings along a climatic gradient of increasing precipitation and elevation. At relatively dry PIPO sites understories were dominated by ponderosa pine. At wetter PIPO/PSME and PIPO ABGC sites understories were dominated by shade tolerant species, but ponderosa pine was dominant in the overstory. At the coolest and wettest PIPO/PSME/ABGC sites understories were dominated by grand fir and shade tolerant species were common in the overstory.
In the eastern Cascades current density of all live trees and snags was 432, 461, 570, 372 trees per hectare (TPH) for the four stand types identified. Stand types in the drier Ochoco Mountains were currently less dense at 279, 304, 212, and 307 TPH. Current MCF densities in both areas are 2-3 times higher than densities estimated for the late 19th and early 20th centuries from other studies in those two areas. Reconstruction of cuts in each stand type indicates that the density of large diameter ponderosa pine has been reduced by approximately 50% in all stand types in both study regions.
Age histograms demonstrate that current density and composition of MCF stand types is a product of abrupt increases in tree establishment following fire exclusion in the late 19th century. The number of trees established increased after 1900 in all stand types, but the timing and composition of changes in establishment varied with climate. At dry PIPO sites increases in establishment were delayed until the 1920s and 1930s and were composed of ponderosa pine. At PIPO/PSME and PIPO/ABGC sites with intermediate precipitation, establishment was dominated by ponderosa pine prior to 1900, but after 1900 establishment was dominated by a large pulse of Douglas-fir and grand fir. At the wettest PIPO/PSME/ABGC there was less evidence of changes in structure and composition over time. My results indicate that compared to dry pine and dry-mixed conifer sites, relatively productive moist mixed-conifer sites were characterized by large changes in structure and composition. Such sites could be considered more ecologically altered by lack of fire than drier forest types that had high fire frequencies but slower rates of stand development and less plant community change.
Radial growth patterns of cored ponderosa pines differed between the eastern Cascades and Ochoco Mountains. In the eastern Cascades mean growth rates and variance decreased during favorable climatic periods after 1900. This is likely related to increased competition, and provides evidence that current stand density lacks a temporal analog in the 18th and 19th centuries. Sensitivity of growth to climate and harvest suggest competition for water in the denser forest of the eastern Cascades, and indicates thinning will increase the diameter growth rate of large old pines. In the Ochoco Mountains, ponderosa pine tree growth was less responsive to climate prior to fire exclusion in the late 1800s, and growth did not respond to fire events. This suggests competition among trees was historically low in this region. After fire exclusion growth became more responsive to wet and dry climatic cycles, which may indicate that increased density and competition made trees more responsive to climate variability. Patterns of slow and fast growth appeared to differ between study regions and likely differ at the sub-regional
scale. Further analysis of the relationship between growth and climate in different environmental settings is needed to distinguish where stand development has been modified by disruption of fire regimes. / Graduation date: 2013
|
Page generated in 0.082 seconds